Partial Design Process These resources engage students in some of the steps in the engineering design process,
but do not have them complete the full process. While some of these resources may focus heavily on the brainstorm and design steps,
others may emphasize the testing and analysis phases.

Summary

Student teams investigate the migration of small-particle plastic pollution by exposing invertebrates found in water samples from a local lake or river to fluorescent bead fragments in a controlled environment of their own designs. Students begin by reviewing the composition of food webs and considering the ethics of studies on live organisms. In their model microcosms, they set up a food web so as to trace the microbead migration from one invertebrate species to another. Students use blacklights and microscopes to observe and quantify their experimental results. They develop diagrams that explain their investigations—modeling the ecological impacts of microplastics.
This engineering curriculum meets Next Generation Science Standards (NGSS).

Engineering Connection

Engineers design and implement municipal and industrial water treatment processes. To monitor the success of discharge and filtration efforts, they routinely test samples of both water and the organisms that depend on the integrity of the local ecosystem. Like engineers, students create model microcosm systems on which they conduct experiments to introduce pollution and then measure and observe the effects of human technology on the natural environment.

Pre-Req Knowledge

It is recommended that students complete the associated lesson prior to conducting this activity.

Learning Objectives

After this activity, students should be able to:

Develop a microcosm that represents a freshwater aquatic food chain.

Monitor the movement of fluorescent microbeads (FMB) within a microcosm environment.

Use microscope skills to quantify, document and record the movement of FMBs.

Present findings in a summary report, including a discussion of the significance of the results.

Present an extrapolation of experimental results, including a food web diagram that illustrates the effects of technology (microbeads) on the environment.

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In the ASN, standards are hierarchically structured: first by source; e.g., by state; within source by type; e.g., science or mathematics;
within type by subtype, then by grade, etc.

Design, evaluate, and refine a solution for reducing the impacts of human activities on the environment and biodiversity.
(Grades 9 - 12)
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Evaluate or refine a technological solution that reduces impacts of human activities on natural systems.
(Grades 9 - 12)
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Students will develop an understanding of the effects of technology on the environment.
(Grades K - 12)
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Students will develop an understanding of the role of troubleshooting, research and development, invention and innovation, and experimentation in problem solving.
(Grades K - 12)
Details...View more aligned curriculum...
Do you agree with this alignment?
Thanks for your feedback!

Design, evaluate, and refine a solution for reducing the impacts of human activities on the environment and biodiversity.
(Grades 9 - 12)
Details...View more aligned curriculum...
Do you agree with this alignment?
Thanks for your feedback!

Evaluate or refine a technological solution that reduces impacts of human activities on natural systems.
(Grades 9 - 12)
Details...View more aligned curriculum...
Do you agree with this alignment?
Thanks for your feedback!

Take a look at this diagram of an aquatic and terrestrial food web. (Give students some time to observe the diagram. Then lead a class discussion about what the lines and labels represent. Suggested prompts are provided below.)

What substances are being transferred from one species to another? (Possible answers: Nutrients, carbon dioxide, etc.)

Do you think that anthropogenic (human-generated) pollution can impact this food web? If so, how? (Have students discuss in small groups and then share as a class. Possible answers: Pollution harms smaller animals, which then affect the larger animals).

In the long term, how might those pollution impacts affect human health and economics? (Possible answers: They affect the quality of drinking water sources; lower the soil nutrient levels, which affect farming, which impact human health and farming costs; harm human health when affected animals are eaten, etc.)

(Next, introduce students to the ethics of animal research.) In today’s investigation, we will test the impact of plastic on an ecosystem and the living things that exist within it. In engineering teams, you will create a small ecosystem that you populate with small living things. To model and investigate what happens in the real world, you will expose the organisms to plastics that may interfere with their health.

What might be some of the pros and cons about this research investigation approach? (Give students time to discuss and record their ideas in small groups. Possible pros: Modeling effects of pollution in a controlled environment to isolate pollution effects, get a detailed view of how pollution travels through the food chain, etc. Possible cons: Harming the organisms as part of the experimental testing; model conditions may not accurately depict the real world, etc.)

(Lead students through an ethics discussion. Suggested prompts are provided below.)

Thinking about all the pros and cons we came up with, why might research like this be beneficial? (Possible answers: To test the pollution effects of emerging pollutants, to test whether emissions from a new or proposed building would impact the balance of the natural environment or human health, etc.)

In what ways might you minimize the harm (the cons)? (Possible answers: Use only the minimum number of animals; carefully record experimental results so that the experiment does not need to be run again, etc.)

What alternate activities can you suggest as ways to investigate the same question? (Possible answers Observe an existing real-world ecosystem; create a computer model, etc.)

Vocabulary/Definitions

anthropogenic: Originating in human activity. For example, having to do with human impact on the environment.

bioindicator: Any species (an “indicator species”) or group of species whose function, population or status reveals the qualitative status of the environment.

biomagnification: The increasing concentration of toxins in an organism as a result of its ingesting other plants or animals in which the toxic substances are less concentrated. The process whereby certain substances work their way into bodies of water and then move up food chains, manifesting in progressively greater concentrations.

food web: A system of interconnected food chains within an ecological community.

microcosm : A simplified, artificial ecosystem used to simulate and predict the behavior of a natural ecosystem under controlled conditions. Also called an experimental ecosystem.

trophic level: Each of several hierarchical levels in an ecosystem, comprising organisms that share the same function in the food chain and the same nutritional relationship to the primary sources of energy. The trophic level of an organism is the position it occupies in a food chain.

Procedure

Before the Activity

Set out material piles for each group and place class materials in a centralized location. Separate the fluorescent microbeads from the rest of the materials.

Prepare a control microcosm into which NO fluorescent microbeads will be added.

Set up a computer and projector to show the Food Web Visual Aid (a PowerPoint® file; same as Figure 1), an aquatic and terrestrial food web.

With the Students

Divide the class into groups of three students each and conduct the pre-activity assessment as described in the Assessment section.

Introduce the activity by presenting the content in the Introduction/Motivation section. This includes examining the food web diagram, discussing ethics issues, and introducing the team research project.

Direct the groups to proceed to create their aquatic microcosms from local aquatic sources (ponds, creeks, lakes, etc.). Permit the teams to collect materials. Make sure each group includes an airstone to provide oxygen and prevent stagnation. Do not provide the fluorescent microbeads yet.

Remind students to carefully write down their experimental procedures, including the amounts and types of materials used, and the types of organisms in their microcosms.

Have teams select aquatic organisms and carefully observe them under magnification. Require groups to include species from three or more connected trophic levels. Have students take photos at this time and during all observations as a way to document their findings. After observations are completed, have students place the organisms in the water.

Give each team no more than one 0.1 mg sample of fluorescent microbeads with which to work in their microcosms. Add the beads to the water surface so they are available to the organisms.

Maintain microcosms with multiple species for at least one week so that acclimation and feeding occurs. During this time, have teams document their qualitative observations.

After one or two weeks, take samples at each trophic level and observe them under magnification using a UV flashlight in a dark space so that fluorescent beads may be observed. Collect quantitative and qualitative data.

After one or two more weeks, collect the remaining organisms and euthanize them in alcohol. Collect data and record observations. Make comparison observations and measurements to the control microcosm.

If possible, filter the water using paper filters. Observe the filtrate for fluorescent beads and additional microorganisms.

Conclude by assigning the post-activity assessment report and reflection writings, as described in the Assessment section.

Attachments

Safety Issues

Avoid the use of fish or other vertebrates because research investigations with these organisms requires approval by an official experimental review board.

Troubleshooting Tips

If unclear about how to find local water with three food chain levels present, get assistance from county extensions or nearby university biology departments who know more about finding aquatic organisms.

Investigating Questions

What is the effect of microplastic pollution on ecosystems? (Answer: Microplastics enter the food chain through small organisms, and accumulates in larger organisms as they eat the smaller organisms. Thus, microplastic pollution can harm the health of organisms in the ecosystem even if they do not directly eat the plastic.)

Assessment

Pre-Activity Assessment

Local Food Chains: Have students describe food chains that they observe in daily life. For example: sunlight > tree > nut > squirrel > hawk OR sunlight > grass > cow > human. Student answers indicate their base understanding of food chains and the interconnectedness of organisms in the natural world.

Activity Embedded Assessment

Observation and Experimentation: As student groups are creating and examining their microcosms, make sure they participate in the following experiment activities:

Take photographs of all organisms present in the microcosm, pre- and post-microplastics addition.

Write a detailed microcosm setup procedure that documents how the experiment was carried out.

Carefully record collected data and results—both quantitative and qualitative, such as: number of organisms ingesting fluorescent microbeads (FMB), percentage FMB uptake per volume of microcosm, average FMB ingestion, etc.

Post-Activity Assessment

Reports and Reflections: Give groups time to reflect on their results through the following assignments:

Write a conclusion/discussion paper that summarizes the project results AND the significance of the results.

Include an extrapolation of the results that includes the impacts of microplastic pollution on four trophic levels of an aquatic ecosystem. Provide a diagram to explain the ecological impacts of microplastics.

Have students observe the microcosm systems for longer periods of time in order to ascertain long-term impacts on various species.

Additional Multimedia Support

Show students a 1:46-minute video, Plankton Munching Microplastics by Bo Eide at https://www.youtube.com/watch?v=2oQeXhURTgY. This video, filmed through a microscope, shows little sea creatures, filter feeders, that are transparent, which enables observation of the accumulation of plastic particles colored with fluorescent dye (little green dots) that have been ingested by the plankton.

Contributors

David Bennett; Sara Hettenbach; William Welch

Copyright

Supporting Program

SHIFTED RET Program, University of Kansas Lawrence and Greenbush

Acknowledgements

This curriculum was based upon work supported by the National Science Foundation under RET grant no. EEC 1301051—Shaping Inquiry from Feedstock to Tailpipe with Education Development (SHIFTED) through the Center for Environmentally Beneficial Catalysis, hosted by the University of Kansas Lawrence and the Southeast Kansas Education Service Center (referred to as Greenbush). Any opinions, findings, and conclusions or recommendations expressed in this material are those of the authors and do not necessarily reflect the views of the National Science Foundation.

Special thanks to Belinda Sturm, Samik Bagchi, Robert Everhart and Rachel Bowes.